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I've been using C++ for a bit now. I'm just never sure how the memory management works, so here it goes:

I'm first of all unsure how memory is unallocated in a function, ex:

int addTwo(int num)
    int temp = 2;
    num += temp;
    return num;

So in this example, would temp be removed from memory after the function ends? If not, how is this done. In C# a variable gets removed once its scope is used up. Are there also any other cases I should know about?


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This code is plain C. Therefore there is no C++ memory management going on here. This would only be the case if "new" would be used to create temp. –  RED SOFT ADAIR Dec 10 '09 at 13:42
Retagged as 'C' because there's no C++ here, as pointed out by someone else below. –  ChrisInEdmonton Dec 10 '09 at 13:45
Tetagged as C++, becaue this is definitely a C++ question, and the questioner explicitly asks about C++. –  anon Dec 10 '09 at 13:47
OP, there is no requirement that you accept any of the answers. –  anon Dec 10 '09 at 14:08
OP, there might be a requirement to sorth through all the comments, though ;) –  peterchen Dec 10 '09 at 14:22

11 Answers 11

up vote 6 down vote accepted

The local variable temp is "pushed" on a stack at the beginning of the function and "popped" of the stack when the function exits.

Here's a disassembly from a non optimized version:

int addTwo(int num)
00411380  push        ebp  
00411381  mov         ebp,esp             //Store current stack pointer
00411383  sub         esp,0CCh            //Reserve space on stack for locals etc
00411389  push        ebx  
0041138A  push        esi  
0041138B  push        edi  
0041138C  lea         edi,[ebp-0CCh] 
00411392  mov         ecx,33h 
00411397  mov         eax,0CCCCCCCCh 
0041139C  rep stos    dword ptr es:[edi] 
    int temp = 2;
0041139E  mov         dword ptr [temp],2 
    num += temp;
004113A5  mov         eax,dword ptr [num] 
004113A8  add         eax,dword ptr [temp] 
004113AB  mov         dword ptr [num],eax 
    return num;
004113AE  mov         eax,dword ptr [num] 
004113B1  pop         edi  
004113B2  pop         esi  
004113B3  pop         ebx  
004113B4  mov         esp,ebp                 //Restore stack pointer
004113B6  pop         ebp  
004113B7  ret

The terms "pushed" and "popped" are merely meant as an analogy. As you can see from the assembly output the compiler reserves all memory for local variables etc in one go by subtracting a suitable value from the stack pointer.

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Not precisely how the stack is used. The function call will allocate a frame on the stack, but no pushes and pops take place. –  anon Dec 10 '09 at 13:39
@Neil I know, It was meant as an analogy which would be easier to understand. Added quotes and some assembly output –  Andreas Brinck Dec 10 '09 at 13:46
push+pop are merely concepts - sure temp is pushed/popped off the stack. The implementation happens to be compiler+architecture dependant, and generally you can expect that the entire frame will be "pushed" and "popped" as one. For historical reasons the focus of the stack implementation is such that the terminology used differs, but we're still talking about placing and removing data from a last-in-first-out data structure: push and pop are certainly not incorrect terms for that. –  Eamon Nerbonne Dec 10 '09 at 13:47
The code makes my point. Theere are no pushes and pops for the local variables, only for the return addresses etc. The storage for the local variables is created by adjusting the stack pointer, and then accessed by indexing. –  anon Dec 10 '09 at 13:49
ahh, you mean the push/pop instructions on x86. Fair enough, that's definitely confusing :-). –  Eamon Nerbonne Dec 10 '09 at 15:49

Normally memory managment is used in the context of dynamic memory that is created by


In the normal code C++ behaves like every other language. If you create a variable or return it, it is copied and accessible on the target side.

int a = addTwo(3);

gets a copy of your returned value. If the returned value is a class copy operator called. So as long as you do not work with new and malloc you do not have to care about memory managment that much.

One additional remark which is important

void func(std::string abc)
  // method gets a copy of abc

void func(std::string& abc)
  // method gets the original string object which can be modified without having to return it

void func(const std::string& abc)
  // method gets the original string object abc but is not able to modify it    

The difference of the three lines is very important because your program may spare a lot of time creating copies of input parameters that you normally didn't want to create.


bool CmpString(std::string a, std::string b)
  return a.compare(b);

is really expensive because the strings a and b are always copied. Use

bool CmpString(const std::string& a, const std::string& b)


This is important because no refcounted objects are used by default.

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In C++ there is a very simple rule of thumb:

All memory is automatically freed when it runs out of scope unless it has been allocated manually.

Manual allocations:

  • Any object allocated by new() MUST be de-allocated by a matching delete().
  • Any memory allocated by malloc() MUST be de-allocated by a matching free().

A very useful design pattern in C++ is called RAII (Resource Acquisition Is Initialization) which binds dynamic allocations to a scoped object that frees the allocation in its destructor.

In RAII code you do not have to worry anymore about calling delete() or free() because they are automatically called whenever the "anchor object" runs out of scope.

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In C++, any object that you declare in any scope will get deleted when the scoped exits. In the example below, the default constructor is called when you declare the object and the destructor is called on exit, ie, ~MyClass.

void foo() {
  MyClass object;

If you declare a pointer in a function, then the pointer itself (the 4 bytes for 32 bit systems) gets reclaimed when the scoped exits, but the memory you might have allocated using operator new or malloc will linger - this is often known as memory leak.

void foo() {
  MyClass* object = new MyClass;
  // leaking sizeof(MyClass) bytes.

If you really must allocate an object via new that needs to be deleted when it exits the scope then you should use boost::scoped_ptr like so:

void foo() {
  boost::scoped_ptr<MyClass> object(new MyClass);
  // memory allocated by new gets automatically deleted here.
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Here, temp is allocated on the stack, and the memory that it uses is automatically freed when the function exits. However, you could allocate it on the heap like this:

int *temp = new int(2);

To free it, you have to do

delete temp;

If you allocate your variable on the stack, this is what typically happens:

When you call your function, it will increment this thing called the 'stack pointer' -- a number saying which addresses in memory are to be 'protected' for use by its local variables. When the function returns, it will decrement the stack pointer to its original value. Nothing is actually done to the variables you've allocated in that function, except that the memory they reside in is no longer 'protected' -- anything else can (and eventually will) overwrite them. So you're not supposed to access them any longer.

If you need the memory allocated to persist after you've exited the function, then use the heap.

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In that example, temp would need to be a pointer. –  Daniel Earwicker Dec 10 '09 at 13:34
int temp = new int(2); is incorrect syntax in C++ –  Prasoon Saurav Dec 10 '09 at 13:35
whoops, fixed (15char) –  int3 Dec 10 '09 at 13:36

In C,C++ local variables have automatic storage class and are stored in Stack.

When function returns then stack gets unwound and locals are no more accessible, but they still persist in memory and that's the reason when u define a variable in function it may contain garbage value.

It is just stack pointer manipulation in stack and on memory for local is removed actually.

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Actually, the C++ specification has no mention of Stack storage. The only mention is the duration of the variable. –  Thomas Matthews Dec 10 '09 at 19:15

Please see my answer to this question. It may clear up a lot of things for oyu.


I'm not just posting a link for giggles. My answer there is an in-depth look (at a very introductory level) how memory management works.

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In this case both num and temp are local to this function. When the function is called the number passed into num is copied from the caller to a variable on the stack. Temp is then created on the stack. When you return the value of num is copied back to the caller, and the temp and num variables used in the function are dropped.

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+1 for pointing out that num is also local. –  ChrisInEdmonton Dec 10 '09 at 13:44

Its not removed from memory once the function exits.

It remains in memory, in addTwo's stack frame, until some other process (or the same) re uses that portion of memory.

Until that point, accessing temp is undefined behaviour.

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True, and this can be important for certain work. However, for most of us, conceptually the memory used by temp is no longer available once the function completes. –  tloach Dec 10 '09 at 13:41
This is never relevant behavior unless you've a pointer to temp. And when you do, this is still never "important for some work" behavior since it's simply a bug. It's worth being aware of the fact that accessing unallocated memory on the stack or heap may result in undefined behavior (i.e. won't necessarily crash or cause an error). I can't see how this matters for any non-buggy functionality. –  Eamon Nerbonne Dec 10 '09 at 13:56
@eamon: All I meant was that for certain work it is important to be aware that your stack size will not shrink just because a bunch of local variables go out of scope. For people who work on hardware where every byte matters being aware of this behavior can inform a decision to allocate space on the stack or the heap. –  tloach Dec 10 '09 at 14:14

temp is allocated on the stack. So when the function returns, it is gone.

C++ scope rules are similar to C#.

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To nitpick, I would say that C# scope rules are similar to C++ since C++ came before C#. –  Thomas Matthews Dec 10 '09 at 19:13
Similar-to is commutative, as far as I know. –  Kristopher Johnson Dec 11 '09 at 0:31

Variable temp is stack allocated. That means it's deallocated when the function returns.

See e.g.:

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Re: C# that is not true of all objects, some are reference type (classes) and some are value types (structs, primatives, enums). –  Daniel Earwicker Dec 10 '09 at 13:36
thanks for the comment. Edited my response accordingly. –  Sebastian Dec 10 '09 at 13:37
Why the downvotes? What's wrong with this answer? –  Graeme Perrow Dec 10 '09 at 13:38

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